JP2005167742A - Dvd recorder and video signal recording apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To record all video signals that are recorded on a digital video tape on an optical disc with no vacant region, even if an actual recording time on the digital video tape is longer than a recording time specified as a specification. <P>SOLUTION: A digital video camcorder 1 comprises a recording time acquiring means 25 which acquires the recording time of the video signal recorded on a digital video tape 11 based on a signal outputted from the digital video camcorder 1 when the digital video tape 11 is fast-forwarded from a top to a record completion position. In an automatic correction mode, a bit rate calculating means 26 records the video signal for recording on an optical disc 23 based on the recording time acquired by the recording time acquiring means 25. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a DVD recorder and a video signal recording apparatus for expanding and encoding a digital video signal output from a digital video camera for playing back a digital video tape, and recording it on an optical disk.

  In a digital video cassette tape, when a tape capable of recording an 80-minute video signal (hereinafter referred to as an 80-minute tape) is used, a 120-minute video signal can be recorded by adopting the long mode. For this reason, when a video signal recorded in the 80-minute tape in the long mode is reproduced, and the video signal obtained by the reproduction is converted into a DVD standard video signal and recorded on the optical disc, the video signal is deteriorated. For the purpose of minimizing, 5 Mbps, which is a bit rate corresponding to a video signal of 120 minutes, is used as a bit rate of a video signal when recording on an optical disc (first conventional technology). .

  Further, the following prior art has been proposed (referred to as a second prior art). That is, in this technique, the remaining recordable amount of the disc is obtained and displayed. For this reason, the user knows the recordable capacity from the displayed remaining amount, and inputs the recording capacity of information to be recorded and the recording time of the information within the remaining amount range. . Then, based on the recording capacity w of the input information and the recording time t, the calculation of R1 = w / t−α is performed to obtain the average transmission rate R1 when recording the video signal. (For example, refer to Patent Document 1).

  Further, the following prior art has been proposed (referred to as third prior art). That is, in this technique, the maximum capacity D that can be recorded on the optical disk is read, and the user's desired recording time T is input. Then, the transfer rate R2 is calculated by calculating R2 = D / T, and a video signal, an audio signal, and the like are recorded on the optical disc with the calculated transfer rate (see, for example, Patent Document 2).

Further, the following prior art has been proposed (fourth prior art). That is, in this technique, the recording time t, which is the recording time of all the programs set to automatic image quality, among the programs reserved for recording is obtained. Then, assuming that the recordable remaining amount is w, the average recording rate R3 at the time of recording is obtained by performing the calculation of R3 = (w−b) / t (b indicates the reserve capacity) (for example, (See Patent Document 3).
JP-A-6-76474 (paragraphs 0022-0024) Japanese Patent Laid-Open No. 10-143999 (paragraphs 0019-0024) Japanese Patent Laid-Open No. 11-176096 (paragraph 0644-0646)

  However, when the first prior art is used, the following problems occur. That is, when a video signal is recorded on the 80-minute tape in the long mode, the recordable recording time exceeds 120 minutes. This makes it possible to record a standard 120-minute video signal even when a minute speed error occurs during the running of the digital video tape, so it is substantially longer than 120 minutes. This is because a digital video tape is manufactured so that a video signal can be recorded. Therefore, when the video signal is recorded on the 80-minute tape in the long mode to the end of the digital video tape, the recording time of the recorded video signal exceeds 120 minutes.

  For this reason, when recording a video signal obtained by reproducing a digital video tape on an optical disc at a bit rate at which a video signal of 120 minutes can be recorded without leaving an empty area, a portion exceeding 120 minutes Cannot be recorded on the optical disc. In other words, when the video signal is recorded to the end of the digital video tape using the long mode on the 80-minute tape, the video signal recorded on the digital video tape is prepared corresponding to the long mode of the 80-minute tape. When recording on an optical disc with the above settings, the video signal recorded on the optical disc is a cut-off video signal.

  For this reason, it is necessary for the user to set a bit rate, perform test recording, and test whether recording can be performed without causing a shortage and without leaving an empty area, which is troublesome. In addition, since the bit rate setting is not appropriate, when the empty area becomes large or a short cut occurs, recording with the bit rate changed again is required. Therefore, when an optical disc that can be written only once is used, the optical disc is unnecessarily consumed.

  In the second prior art, the recording time is input by the user. For this reason, when trying to solve the problem that occurs in the first prior art, that is, the part that the recording time exceeds 120 minutes in the video signal recorded on the digital video tape is not recorded on the optical disk. Has become a technology that is difficult to apply.

  In the third prior art, similarly, the desired recording time is input by the user. For this reason, when trying to solve the problem that occurs in the first prior art, that is, the part that the recording time exceeds 120 minutes in the video signal recorded on the digital video tape is not recorded on the optical disk. Has become a technology that is difficult to apply.

  Similarly, in the fourth prior art, the recording time is determined by the portion set as the automatic image quality in the recording reservation program set by the user. For this reason, when trying to solve the problem that occurs in the first prior art, that is, the part that the recording time exceeds 120 minutes in the video signal recorded on the digital video tape is not recorded on the optical disk. Has become a difficult technology to apply.

  The present invention was devised to solve the above-mentioned problems, and was recorded on a digital video tape even when the substantial recording time of the digital video tape was longer than the recording time determined as a standard. All video signals can be recorded on an optical disc without causing a free space, and the image signal recorded on the optical disc can be prevented from partial deterioration in image quality. An object of the present invention is to provide a DVD recorder capable of suppressing the complicated operation.

  Another object of the present invention is to acquire the recording time of the video signal recorded on the digital video tape based on the signal obtained when the digital video tape is fast-forwarded from the start position to the recording end position. By calculating the bit rate of the video signal for recording based on the recording time, the video recorded on the digital video tape can be used even when the actual recording time of the digital video tape is longer than the standard recording time. It is an object of the present invention to provide a video signal recording apparatus capable of recording all signals on an optical disk without causing an empty area.

  In addition to the above purpose, by setting the bit rate of the recording video signal to a constant value from the start to the end of recording on the optical disc, partial deterioration of the image quality of the video signal recorded on the optical disc is prevented. An object of the present invention is to provide a video signal recording apparatus capable of performing the above.

  In addition to the above purpose, the bit rate of the video signal for recording is reduced on the end side of recording of the video signal for recording on the optical disc, thereby preventing deterioration of image quality in the majority of the video signal recorded on the optical disc. Another object of the present invention is to provide a video signal recording apparatus capable of minimizing the time during which deterioration occurs when image quality deterioration occurs.

  Another object of the present invention is to provide a video signal recording apparatus capable of suppressing the complexity of key operations for shifting to the automatic correction mode without increasing the number of key switches.

  In order to solve the above problems, a DVD recorder according to the present invention is a recording video that is a video signal for recording a playback video signal that is a digital video signal output from a digital video camera that plays back a digital video tape on an optical disc. The present invention is applied to a DVD recorder including signal conversion means for converting a signal into a signal and bit rate calculation means for calculating a bit rate when the reproduced video signal is converted into a recording video signal and recorded on an optical disc. Based on the automatic dubbing key provided on the remote controller and the signal output from the digital video camera when the digital video tape is fast-forwarded from the beginning position to the recording end position in the digital video camera, Recording time acquisition means for acquiring the recording time of the recorded video signal, and when the automatic dubbing key is operated, the recording time acquisition means causes the recording time of the video signal recorded on the digital video tape to be acquired; The bit rate calculation means is a bit rate for recording the recording video signal on the optical disc based on the recording time acquired by the recording time acquisition means, and from the start to the end of recording of the recording video signal on the optical disc. The bit rate as a constant value applied up to By causing the signal conversion according to the bit rate calculated by the bit rate calculation means to the means, the recording video signal is adapted to record on the optical disk.

  That is, in the case of calculating the bit rate based on the recording time acquired by the recording time acquisition means, all the video signals recorded on the digital video tape are not cut off and free space is not generated. It is possible to obtain an optimum bit rate when recording on the optical disc. In addition, the image quality of the video signal recorded on the optical disc is maintained at a constant image quality from the start to the end of recording. In addition, the dubbing of the video signal recorded on the digital video tape to the optical disk can be started only by operating the automatic dubbing key once.

  The video signal recording apparatus according to the present invention also converts a playback video signal, which is a digital video signal output from a digital video camera that plays back a digital video tape, into a recording video signal that is a video signal to be recorded on an optical disc. The present invention is applied to a video signal recording apparatus provided with signal conversion means and bit rate calculation means for calculating a bit rate for converting a reproduced video signal into a recording video signal and recording it on an optical disc. Then, the recording time of the video signal recorded on the digital video tape is acquired based on the signal output from the digital video camera when the digital video tape is fast-forwarded from the start position to the recording end position in the digital video camera. When the recording time acquisition unit is provided and the automatic correction mode is set, the bit rate calculation unit calculates the bit rate for recording the recording video signal on the optical disc based on the recording time acquired by the recording time acquisition unit. It is like that.

  That is, in the case of calculating the bit rate based on the recording time acquired by the recording time acquisition means, all the video signals recorded on the digital video tape are not cut off and free space is not generated. It is possible to obtain an optimum bit rate when recording on the optical disc.

  In addition to the above configuration, the bit rate calculated by the bit rate calculation means is a constant value applied from the start to the end of recording of the recording video signal on the optical disc. That is, the image quality of the video signal recorded on the optical disc is maintained at a constant image quality from the start to the end of recording.

  In addition to the above configuration, the bit rate calculated by the bit rate calculating means decreases on the end side of recording of the recording video signal onto the optical disc. That is, the image quality is not deteriorated in the video signal recorded in most of the period when the end of recording is not approaching.

  In addition to the above configuration, a setting key that displays a menu screen related to the setting is provided, and the transition to the automatic correction mode can be selected on the menu screen that is displayed first when the setting key is operated when the operation is stopped. ing. That is, only the three types of key operations, ie, the setting key operation for displaying the menu screen, the key operation for moving the cursor, and the key operation for inputting the decision, are performed to shift to the automatic correction mode. be able to.

  According to the present invention, since the bit rate is calculated based on the recording time acquired by the recording time acquisition means, all of the video signals recorded on the digital video tape are not cut off and free space is generated. It is possible to obtain an optimum bit rate when recording on the optical disc without any occurrence. The image quality of the video signal recorded on the optical disc is maintained at a constant image quality from the start to the end of recording. Also, the dubbing of the video signal recorded on the digital video tape to the optical disk can be started by a single key operation of the automatic dubbing key. Therefore, even when the substantial recording time of the digital video tape is longer than the recording time determined as a standard, all the video signals recorded on the digital video tape can be recorded on the optical disk, and the optical disk It is possible to prevent the deterioration of the partial image quality of the video signal recorded on the recording medium and to suppress the complication of key operation in dubbing.

  Further, according to the present invention, since the bit rate is calculated based on the recording time acquired by the recording time acquisition means, all the video signals recorded on the digital video tape are not cut off and Since it is possible to obtain the optimum bit rate when recording on an optical disc without creating free space, even when the actual recording time of digital video tape is longer than the standard recording time All of the video signals recorded on the digital video tape can be recorded on the optical disc without causing a free space.

  Furthermore, since the image quality of the video signal recorded on the optical disc is maintained at a constant image quality from the start to the end of recording, it is possible to prevent partial deterioration of the image quality of the video signal recorded on the optical disc. it can.

  Furthermore, image quality is not deteriorated in the video signal recorded in most of the period when the end of recording is not approaching, so that deterioration in image quality is prevented in most of the video signal recorded on the optical disc and image quality is improved. Even when deterioration occurs, the time during which deterioration occurs can be minimized.

  Furthermore, only the three types of key operations are required to enter the automatic correction mode: the setting key operation for displaying the menu screen, the key operation for moving the cursor, and the key operation for inputting the decision. Therefore, the complexity of the key operation for shifting to the automatic correction mode can be suppressed without increasing the number of key switches.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a block diagram showing an electrical configuration of a DVD recorder which is an embodiment of a video signal recording apparatus according to the present invention.

  In the figure, a cable 2c and connectors 2a and 2b that connect the apparatus main body 31 of the DVD recorder and the digital video camera 1 are cables and connectors of a standard defined as IEEE1394. The connector 2a is provided at the end of the cable 2c, and the connector 2b is attached to the apparatus main body 31 side of the DVD recorder.

  The communication control means 3 exchanges information with the digital video camera 1 by a communication method according to the IEEE 1394 standard. Then, information output from the digital video camera 1 in the exchange of information (information indicating the model, information indicating a list of commands that can be accepted, etc.) is output to the microcomputer 5. Information such as commands output from the microcomputer 5 is output to the digital video camera 1. In addition, a digital video signal (hereinafter referred to as a playback video signal) output from the digital video camera 1 is sent to the DV decoder 27.

  The digital video camera 1 records a digital video signal indicating a captured video on a digital video tape 11 set therein. Also, the digital video signal recorded on the digital video tape 11 is reproduced, and the digital video signal (reproduced video signal) obtained by the reproduction is output to the communication control means 3 through the cable 2c and the connectors 2a and 2b. To do.

  In addition, a list of commands that can be accepted among various commands indicating operations as a digital video camera, such as a playback command, a fast-forward command, and a rewind command, is output to the communication control means 3. When one of the commands that can be accepted is given from the microcomputer 5 via the communication control means 3, the operation indicated by the command is executed.

  The DV decoder (hereinafter simply referred to as a decoder) 27 decompresses the reproduced video signal in accordance with the DV standard because the reproduced video signal is a DV standard (standard conforming to the SD specification in the digital VTR). To do. The decompressed digital video signal is output to an MPEG2 encoder (hereinafter simply referred to as an encoder) 28. The encoder 28 encodes the digital video signal output from the decoder 27 to generate an optical disc standard digital video signal (a signal encoded according to the MPEG2 standard, hereinafter referred to as a recording video signal). To do. Then, the generated recording video signal is output to the recording / reproducing signal circuit 6.

  That is, the block 4 composed of the decoder 27 and the encoder 28 is the signal converting means described in the claims, and the reproduced video signal output from the digital video camera 1 is converted into a digital video of the optical disc standard such as DVD-R. The signal is converted into a recording video signal used when recording on the recordable optical disc 23 (the audio signal is not shown).

  The recording / reproducing signal circuit 6 generates a drive signal for driving the pickup 22 based on the recording video signal output from the signal conversion unit 4 and outputs the drive signal to the pickup 22 during recording. At the time of reproduction, an RF signal is extracted from the signal output from the pickup 22 and output to the reproduction signal processing means 7.

  At the time of recording, the pickup 22 writes a recording video signal on the optical disk 23 that is rotationally driven by the spindle motor 21 in accordance with the drive signal output from the recording / reproducing signal circuit 6. At the time of reproduction, a signal obtained by reading the data recorded on the optical disk 23 is output to the recording / reproduction signal circuit 6 (the signal path for servo control is not shown).

  The reproduction signal processing means 7 performs error correction after decoding the digital data from the RF signal output from the recording / reproduction signal circuit 6. Next, the video stream obtained by error correction is decompressed according to the MPEG2 standard, and then D / A converted. Then, an analog video signal which is a signal obtained by D / A conversion is output to the television receiver 10. Further, after decompressing the audio stream, an analog audio signal obtained by D / A conversion is output to the television receiver 10.

  The input means 8 includes a plurality of key switches (not shown) provided on the front panel of the apparatus main body 31, a light receiving unit (not shown) that receives an infrared signal transmitted from the remote controller 9, and the like. Thus, an instruction from the user is input. When an instruction from the user is input, the input instruction is sent to the microcomputer 5.

  The microcomputer 5 controls main operations as a DVD recorder. That is, when the reproduced video signal output from the digital video camera 1 is recorded on the optical disc 23, the operation of the decoder 27 and the operation of the encoder 28 are controlled. Further, when the video signal recorded on the optical disk 23 is reproduced, the operation of the reproduction signal processing means 7 is controlled. Further, an external device control unit 24, a recording time acquisition unit 25, and a bit rate calculation unit 26 are formed by a part of the functions.

  In this embodiment, two modes, a normal mode and an automatic correction mode, are prepared as modes for recording the playback video signal output from the digital video camera 1 on the optical disc 23. One of two modes can be selected.

  The external device control unit 24 acquires a list of commands that the digital video camera 1 can accept from the information obtained via the communication control unit 3. Then, from the list of acquired commands, a command necessary at that time is selected and output to the digital video camera 1 to control the operation of the digital video camera 1.

  That is, when recording the reproduced video signal on the optical disk 23 using the automatic correction mode, the digital video tape 11 set in the digital video camera 1 is rewound to the head and then fast-forwarded. Then, when fast-forwarding is completed, control is performed to rewind to the beginning and then start reproduction.

  The recording time acquisition means 25 records the video signal recorded on the digital video tape 11 based on the signal output from the digital video camera 1 when the digital video camera 1 is fast-forwarding the digital video tape 11. Get time. That is, when the digital video tape 11 is fast-forwarded in the digital video camera 1, a control signal is output from the digital video camera 1 when a video signal is recorded in a portion passing through the head. In addition, a time stamp indicating the recording time is output.

  For this reason, the recording time acquisition means 25 counts the number of control signals during fast-forwarding. Then, the recording time of the video signal recorded on the digital video tape 11 is calculated from the counting result. Further, the recording time of the video signal recorded on the digital video tape 11 is calculated based on the time stamp value output from the digital video camera 1 during fast-forwarding (only one of these two methods is used. Good).

  The bit rate calculating means 26 calculates the bit rate of the recording video signal when recording the recording video signal on the optical disc 23. Specifically, in the normal mode, when the digital video tape 11 played back in the digital video camera 1 is, for example, an 80-minute tape capable of recording for 80 minutes, and the recording method is in the long mode, the digital video tape 11 is digital. Assuming that the video signal recorded on the video tape 11 is 2 hours, the bit rate required for recording the video signal for 2 hours on the optical disc 23 without generating a free space is calculated. Then, the encoder 28 is controlled so that the encoding bit rate in the encoder 28 becomes the calculated bit rate.

  On the other hand, in the case of the automatic correction mode, the digital video tape 11 reproduced by the digital video camera 1 is, for example, an 80-minute tape capable of recording for 80 minutes, and the digital video tape 11 is digital even when the recording method is in the long mode. The video signal recorded on the video tape 11 is considered to be substantially longer than 2 hours or less than 2 hours. Therefore, the bit rate for recording the recording video signal on the optical disk 23 is calculated based on the substantial recording time of the video signal recorded on the digital video tape 11.

  That is, since the recording time acquired by the recording time acquisition unit 25 indicates a substantial recording time of the video signal recorded on the digital video tape 11, the bit rate calculation unit 26 acquires it by the recording time acquisition unit 25. A bit rate corresponding to the recorded recording time is calculated.

  Therefore, when the recording time is less than 2 hours, the bit rate corresponding to the recording time less than 2 hours is calculated. When the recording time exceeds 2 hours, a bit rate corresponding to the recording time exceeding 2 hours is calculated. After the bit rate is calculated, the encoder 28 is controlled so that the encoding bit rate in the encoder 28 becomes the calculated bit rate.

  As described above, the present embodiment is configured to have two modes, the normal mode and the automatic correction mode, as modes for recording the video signal recorded on the digital video tape 11 on the optical disc 23. .

  A tuner unit for receiving commercial broadcasts and an A / D conversion unit for converting an analog video signal output from the tuner unit into a digital video signal and outputting it to the encoder 28 are provided. The illustration is omitted.

  FIG. 2 is an explanatory diagram showing a part of key switches provided in the remote controller 9, and 41 is four key switches mainly used when reproducing the optical disc 23, and includes a reproduction key and a fast-forward key. , Fast reverse key, stop key. Reference numeral 42 denotes a setting key for displaying a menu screen for performing various settings as a device.

  43 is a key switch for changing the operation mode from the normal mode to the automatic correction mode and for automatically recording the video signal recorded on the digital video tape 11 on the optical disc 23 (hereinafter referred to as an automatic dubbing key). It has become. Reference numeral 44 denotes a recording key for starting an operation of recording a video signal on the optical disc 23. Reference numeral 45 denotes a key switch used for selecting an item by moving the cursor.

  FIG. 3 is a flowchart showing the main operation of the embodiment when the reproduced video signal output from the digital video camera 1 is recorded on the optical disc 23. The operation of the embodiment will be described with reference to FIG.

  Assume that the digital video camera 1 is connected to the apparatus main body 31 via the cable 2c, the connector 2a, and the connector 2b (when the external device control unit 24 is informed that the digital video camera 1 is connected). A model name and a list of commands that can be accepted are acquired from the digital video camera 1 and stored in the inside). Further, it is assumed that the digital video tape 11 set in the digital video camera 1 is an 80-minute tape and a video signal is recorded using the long mode.

  Thereafter, it is assumed that the user operates the automatic dubbing key 43 in order to record the video signal recorded on the digital video tape 11 on the optical disc 23 without causing the tail to be cut off (step S1). When the automatic dubbing key 43 is operated, the microcomputer 5 switches the recording mode from the normal mode to the automatic correction mode. Further, the microcomputer 5 uses the on-screen display circuit (not shown) in the reproduction signal processing means 7 to display on the television receiver 10 that automatic dubbing that does not cause a shortage has started. (Step S2).

  Next, the external device control means 24 gives a rewind instruction to the digital video camera 1 by referring to the list of acquired commands. Therefore, the digital video camera 1 rewinds the digital video tape 11 to the top in accordance with the instruction (step S3). Next, the external device control means 24 starts fast-forwarding of the digital video tape 11 by giving a fast-forwarding instruction to the digital video camera 1 (step S4).

  When fast-forwarding of the digital video tape 11 is started, the digital video camera 1 outputs a control signal recorded on the digital video tape 11 together with a video signal. Since this control signal is guided to the microcomputer 5 via the communication control means 3, the recording time acquisition means 25 in the microcomputer 5 counts the control signal (steps S5 and S6).

  When the output of the control signal is stopped, the operation moves to step S7. In step S7, the recording time acquisition unit 25 calculates the recording time of the video signal recorded on the digital video tape 11 from the count value of the control signal (the control signal is a signal recorded together with the video signal). Therefore, the number of control signals indicates the recording time of the video signal).

  When the video signal is recorded on the digital video tape 11 in the long mode to the end of the tape, as described above, the substantial recording time of the video signal exceeds 120 minutes. For this reason, the recording time calculated in step S8 is a value such as 124 minutes or 126 minutes.

  The bit rate calculation means 26 calculates the bit rate of the signal recorded on the optical disc 23 from the recording time calculated by the recording time acquisition means 25 (step S8). The bit rate calculated at this time is a value for recording the video signal for the recording time calculated by the recording time acquisition means 25 exactly on the optical disc 23 without leaving an empty area. . Therefore, the bit rate calculated at this time is, for example, a value of about 4.8 Mbps or about 4.75 Mbps.

  Thereafter, the external device control means 24 gives a rewind instruction to the digital video camera 1 to cause the digital video tape 11 to rewind (step S9). Then, after rewinding to the beginning, the reproduction of the digital video tape 11 is started by giving a reproduction instruction (step S10). Therefore, a playback video signal is output from the digital video camera 1.

  The reproduced video signal is guided to the decoder 27 via the communication control means 3 and expanded. Next, the decompressed signal is guided to the encoder 28 and encoded with a compression rate corresponding to the bit rate calculated by the bit rate calculation means 26. The encoded signal (recording video signal) is recorded on the optical disc 23 via the recording / reproducing signal circuit 6 (step S11).

  From the above, when the automatic dubbing key 43 is operated, the recording time of the video signal recorded on the digital video tape 11 exceeds 120 minutes (for example, 124 minutes or 126 minutes, etc.) In addition, all of the video signals recorded on the digital video tape 11 are automatically generated at a bit rate that fits perfectly in the recordable data area of the optical disc 23 without causing a gap and leaving no free space. Will be recorded.

  The second embodiment will be described below. When shown as an electrical configuration, the second embodiment is the same as the configuration shown in FIG. 1, and only the configuration of the bit rate calculation means 26 is different. For this reason, only the bit rate calculation means 26 will be described.

  The bit rate calculation means 26 calculates the bit rate when the recording video signal, which is a signal encoded by the encoder 28, is recorded on the optical disc 23 so that the bit rate decreases as the end of recording approaches. I do. That is, when the recording time of the video signal is 120 minutes, the bit rate at the start of recording is a value for recording the video signal on the optical disc 23 without generating an empty area (hereinafter referred to as a specified bit rate). Called).

  Then, when it is assumed that the video signal for the recording time calculated by the recording time acquisition unit 25 is recorded on the optical disc 23 using the specified bit rate, the length of the video signal that becomes unrecordable due to the absence of a free area. Based on the above, the bit rate when the end of recording approaches is calculated. That is, it is assumed that, among video signals to be recorded, for example, a video signal of 90 minutes from the start is recorded at a specified bit rate. After that, the bit rate necessary for recording the remaining video signal in the free space remaining on the optical disc 23 without causing a shortage is calculated.

  Specifically, when the recording time calculated by the recording time acquisition unit 25 is h (h> 120) minutes, the bit rate calculation unit 26 is 90 minutes from the beginning (can be other values). The bit rate value for recording the video signal is set to a specified bit rate of 5.0 Mbps. For the remaining (h-90) video signals, the free space on the optical disk 23 is 30 minutes when converted to the time when the bit rate is set to 5.0 Mbps. The bit rate R necessary for recording −90) video signals is obtained (R = 5.0 Mbps × 30 / (h−90)).

  When recording is started, the compression rate in the encoder 28 is set to a value corresponding to a bit rate of 5.0 Mbps for 90 minutes from the start of recording. After 90 minutes, the compression rate in the encoder 28 is set to a value corresponding to the bit rate R.

  The operation of the second embodiment configured as described above is shown as a flowchart in FIG. 3 when shown in a flowchart, and only the operations in steps S8 and S11 are different from those in the first embodiment. For this reason, about operation | movement of 2nd Embodiment, only the operation | movement in step S8, S11 is demonstrated.

  Now, assuming that the recording time calculated by the recording time acquisition unit 25 is, for example, 126 minutes, in step S8, the bit rate calculation unit 26 determines the bit in the period from the start of recording until 90 minutes elapses. The rate is 5.0 Mbps. The bit rate in the subsequent period is set to a value R obtained by performing the calculation (R = 5.0 Mbps × 30/36).

  From the above, in step S11, the encoder 28 performs encoding so that the bit rate is 5.0 Mbps during the period from the start of recording until 90 minutes elapses. Thereafter, the encoder 28 performs encoding so that the bit rate becomes R. For this reason, the reproduced video signal of 126 minutes is recorded exactly in the recordable area of the video signal on the optical disc 23 without causing a shortage and without generating an empty area.

  The third embodiment will be described below. The third embodiment, when shown as an electrical configuration, is the same as the configuration shown in FIG. 1, the configuration of the key switch of the remote controller 9 and when the recording is performed on the optical disc 23 by shifting to the automatic correction mode. Only the operation method of the key switch is different. Therefore, only the parts different from the first embodiment in the description of the key switch of the remote controller 9 and the configuration of the microcomputer 5 will be described.

  The key switch 43 in the remote controller 9 is an automatic dubbing key in the first embodiment, but the automatic dubbing key is omitted in the third embodiment. In one embodiment, it is used as a key switch for inputting an instruction) assigned to a different key switch. Therefore, in the second embodiment, when compared with the first embodiment, the number of key switches can be reduced by one.

  On the other hand, when the setting key 42 is operated when the microcomputer 5 is in a stop state (equivalent to a state immediately after the power is turned on) waiting for an instruction for reproduction or the like from the user, the menu screen shown in FIG. Control for displaying on the machine 10 is performed.

  In this menu screen, an icon 101 for shifting to playback settings, which is one type of setting for the device, an icon 102 for shifting to channel settings, which is one type of setting for the device, scheduled recording, etc. The icon 103 for shifting to the setting relating to the recording of the image and the icon 104 for shifting to the automatic correction mode are displayed (the icon 104 is displayed only when the digital video camera 1 is connected, and the digital video camera 1 If is not connected, it is unnecessary and is not displayed). In addition, icons 105 and 106 for other settings are displayed.

  In the state where the menu screen shown in FIG. 4 is displayed, when the cursor is moved to the icon 104 and the enter key is operated, the microcomputer 5 considers that an instruction to shift to the automatic correction mode has been input. Then, when the recording key 44 is operated, the microcomputer 5 performs the recording operation in the automatic correction mode (the video signal recorded on the digital video tape 11 set in the digital video camera 1 is not cut off, In addition, the recording operation of the optical disc 23 is recorded in the recording area of the optical disc 23 without generating a free space, and the operation including steps S3 to S11 in FIG. 3 is started.

  When the menu screen shown in FIG. 4 is displayed with the digital video camera 1 connected, when the initial position of the cursor is the icon 104, the key operation for shifting to the automatic correction mode is the enter key. As only the operation is performed, usability can be further improved.

  The present invention is not limited to the above embodiment, and the recording time acquisition unit 25 calculates the recording time of the video signal recorded on the digital video tape 11 based on the control signal output from the digital video camera 1. In the above description, the recording time is calculated based on the time stamp output from the digital video camera 1 when the digital video tape 11 is fast-forwarded, or between the control signal and the time stamp. The recording time can be calculated based on both.

  In the second embodiment, the case where the bit rate is reduced by one level on the recording end side has been described. However, the bit rate is decreased by two levels or three levels. can do.

It is a block diagram which shows the electric constitution of the DVD recorder which is one Embodiment of the video signal recording device based on this invention. It is explanatory drawing which shows a part of key switch provided in the remote controller. It is a flowchart which shows the main operation | movement of embodiment when recording the video signal recorded on the digital video tape on an optical disk. It is explanatory drawing which shows the menu screen displayed when a setting key is operated in 3rd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Digital video camera 4 Signal conversion means 9 Remote controller 11 Digital video tape 23 Optical disk 24 External apparatus control means 25 Recording time acquisition means 26 Bit rate calculation means 31 Apparatus main body 43 Automatic dubbing key 104 Icon which shows automatic correction mode

Claims (5)

A signal conversion means for converting a reproduction video signal, which is a digital video signal output from a digital video camera for reproducing a digital video tape, into a recording video signal which is a video signal to be recorded on an optical disc;
In a DVD recorder comprising bit rate calculation means for calculating a bit rate when a reproduced video signal is converted into a recording video signal and recorded on an optical disc,
An automatic dubbing key provided on the remote controller;
Recording time for acquiring the recording time of the video signal recorded on the digital video tape based on the signal output from the digital video camera when the digital video tape is fast-forwarded from the beginning position to the recording end position in the digital video camera Acquisition means,
When the automatic dubbing key is operated, the recording time acquisition means acquires the recording time of the video signal recorded on the digital video tape, and the bit rate calculation means based on the recording time acquired by the recording time acquisition means, This is the bit rate for recording the recording video signal on the optical disc, and calculates the bit rate as a constant value applied from the start to the end of recording of the recording video signal on the optical disc, and causes the signal conversion means to A DVD recorder characterized in that a recording video signal is recorded on an optical disc by performing signal conversion in accordance with the bit rate calculated by the bit rate calculating means. A signal conversion means for converting a reproduction video signal, which is a digital video signal output from a digital video camera for reproducing a digital video tape, into a recording video signal which is a video signal to be recorded on an optical disc;
In a video signal recording apparatus comprising: a bit rate calculating means for calculating a bit rate when a reproduced video signal is converted into a recording video signal and recorded on an optical disc;
Recording time for acquiring the recording time of the video signal recorded on the digital video tape based on the signal output from the digital video camera when the digital video tape is fast-forwarded from the beginning position to the recording end position in the digital video camera An acquisition means,
In the automatic correction mode, the bit rate calculating means calculates a bit rate for recording the recording video signal on the optical disc based on the recording time acquired by the recording time acquiring means. Recording device. 3. The video signal recording apparatus according to claim 2, wherein the bit rate calculated by the bit rate calculating means is a constant value applied from the start to the end of recording of the recording video signal on the optical disc. . 3. The video signal recording apparatus according to claim 2, wherein the bit rate calculated by the bit rate calculating means decreases on the end side of recording of the video signal for recording on the optical disc. It has setting keys to display menu screens related to settings,
5. The shift to the automatic correction mode can be selected on a menu screen that is displayed first when the setting key is operated in the operation stop state. 6. Video signal recording device.

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